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Having briefly looked at Haskell recently I wondered whether anybody could give a brief, succinct, practical explanation as to what a monad essentially is? I have found most explanations I've come across to be fairly inaccessible and lacking in practical detail, so could somebody here help me?

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Eric Lippert wrote an answer to this questions (stackoverflow.com/questions/2704652/…), which is due to some issues lives in a separate page. –  Pavel Shved Apr 25 '10 at 5:24
possible duplicate of Can anyone explain Monads? –  Roger Pate May 27 '10 at 1:10
This article got me closer than any others to understanding monads: ertes.de/articles/monads.html –  sarnold Jan 31 '11 at 2:17
Here's a new introduction using javascript - I found it very readable. –  Benjol Mar 31 '11 at 20:57
See also Different ways to see a monad. –  Petr Pudlák Sep 27 '12 at 8:56

41 Answers 41

The easiest way to grok them (at least for me) is as "decorators", adding behavior while preserving the underlying semantics. Or, an even dirtier definition: it's functional programming's operator overloading.

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No, this is a really bad couple of analogies. –  Peaker Jul 22 '10 at 23:33
I would actually say it is the reverse. They allow you to compose "decorated types" (Task<T>, IEnumerable<T>, Nullable<T> etc) AS IF they were just T. –  Tormod May 12 '11 at 17:32

If you can read ML syntax, a short, accessible explanation with practical, simple code is here.

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Explaining monads seems to be like explaining control-flow statements. Imagine that a non-programmer asks you to explain them?

You can give them an explanation involving the theory - Boolean Logic, register values, pointers, stacks, and frames. But that would be crazy.

You could explain them in terms of the syntax. Basically all control-flow statements in C have curly brackets, and you can distinguish the condition and the conditional code by where they are relative to the brackets. That may be even crazier.

Or you could also explain loops, if statements, routines, subroutines, and possibly co-routines.

Monads can replace a fairly large number of programming techniques. There's a specific syntax in languages that support them, and some theories about them.

They are also a way for functional programmers to use imperative code without actually admitting it, but that's not their only use.

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Princess's explanation of F# Computation Expressions helped me, though I still can't say I've really understood.

EDIT: this series - explaining monads with javascript - is the one that 'tipped the balance' for me.

I think that understanding monads is something that creeps up on you. In that sense, reading as many 'tutorials' as you can is a good idea, but often strange stuff (unfamiliar language or syntax) prevents your brain from concentrating on the essential.

Some things that I had difficulty understanding:

  • Rules-based explanations never worked for me, because most practical examples actually require more than just return/bind.
  • Also, calling them rules didn't help. It is more a case of "there are these things that have something in common, let's call the things 'monads', and the bits in common 'rules'".
  • Return (a -> M<a>) and Bind (M<a> -> (a -> M<b>) -> M<b>) are great, but what I could never understand is HOW Bind could extract the a from M<a> in order to pass it into a -> M<b>. I don't think I've ever read anywhere (maybe it's obvious to everyone else), that the reverse of Return (M<a> -> a) has to exist inside the monad, it just doesn't need to be exposed.
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I'm trying to understand monads as well. It's my version:

Monads are about making abstractions about repetitive things. Firstly, monad itself is a typed interface (like an abstract generic class), that has two functions: bind and return that have defined signatures. And then, we can create concrete monads based on that abstract monad, of course with specific implementations of bind and return. Additionally, bind and return must fulfill a few invariants in order to make it possible to compose/chain concrete monads.

Why create the monad concept while we have interfaces, types, classes and other tools to create abstractions? Because monads give more: they enforce rethinking problems in a way that enables to compose data without any boilerplate.

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In the Coursera "Principles of Reactive Programming" training - Erik Meier describes them as:

"Monads are return types that guide you through the happy path." -Erik Meijer
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I'm going to shoot for a very simple answer:

Monads are an abstraction that provide an interface for encapsulating values, for computing new encapsulated values, and for unwrapping the encapsulated value.

What's convenient about them in practice is that they provide a uniform interface for creating data types that model state while not being stateful.

It's important to understand that a Monad is an abstraction, that is, an abstract interface for dealing with a certain kind of data structure. That interface is then used to build data types that have monadic behavior.

You can find a very good and practical introduction here: http://moonbase.rydia.net/mental/writings/programming/monads-in-ruby/00introduction.html

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This answer begins with a motivating example, works through the example, derives an example of a monad, and formally defines "monad".

Consider these three functions in pseudocode:

f(<x, messages>) := <x, messages "called f. ">
g(<x, messages>) := <x, messages "called g. ">
wrap(x)          := <x, "">

f takes an ordered pair of the form <x, messages> and returns an ordered pair. It leaves the first item untouched and appends "called f. " to the second item. Same with g.

You can compose these functions and get your original value, along with a string that shows which order the functions were called in:

= f(g(<x, "">))
= f(<x, "called g. ">)
= <x, "called g. called f. ">

You dislike the fact that f and g are responsible for appending their own log messages to the previous logging information. (Just imagine for the sake of argument that instead of appending strings, f and g must perform complicated logic on the second item of the pair. It would be a pain to repeat that complicated logic in two -- or more -- different functions.)

You prefer to write simpler functions:

f(x)    := <x, "called f. ">
g(x)    := <x, "called g. ">
wrap(x) := <x, "">

But look at what happens when you compose them:

= f(g(<x, "">))
= f(<<x, "">, "called g. ">)
= <<<x, "">, "called g. ">, "called f. ">

The problem is that passing a pair into a function does not give you what you want. But what if you could feed a pair into a function:

  feed(f, feed(g, wrap(x)))
= feed(f, feed(g, <x, "">))
= feed(f, <x, "called g. ">)
= <x, "called g. called f. ">

Read feed(f, m) as "feed m into f". To feed a pair <x, messages> into a function f is to pass x into f, get <y, message> out of f, and return <y, messages message>.

feed(f, <x, messages>) := let <y, message> = f(x)
                          in  <y, messages message>

Notice what happens when you do three things with your functions:

First: if you wrap a value and then feed the resulting pair into a function:

  feed(f, wrap(x))
= feed(f, <x, "">)
= let <y, message> = f(x)
  in  <y, "" message>
= let <y, message> = <x, "called f. ">
  in  <y, "" message>
= <x, "" "called f. ">
= <x, "called f. ">
= f(x)

That is the same as passing the value into the function.

Second: if you feed a pair into wrap:

  feed(wrap, <x, messages>)
= let <y, message> = wrap(x)
  in  <y, messages message>
= let <y, message> = <x, "">
  in  <y, messages message>
= <x, messages "">
= <x, messages>

That does not change the pair.

Third: if you define a function that takes x and feeds g(x) into f:

h(x) := feed(f, g(x))

and feed a pair into it:

  feed(h, <x, messages>)
= let <y, message> = h(x)
  in  <y, messages message>
= let <y, message> = feed(f, g(x))
  in  <y, messages message>
= let <y, message> = feed(f, <x, "called g. ">)
  in  <y, messages message>
= let <y, message> = let <z, msg> = f(x)
                     in  <z, "called g. " msg>
  in <y, messages message>
= let <y, message> = let <z, msg> = <x, "called f. ">
                     in  <z, "called g. " msg>
  in <y, messages message>
= let <y, message> = <x, "called g. " "called f. ">
  in <y, messages message>
= <x, messages "called g. " "called f. ">
= feed(f, <x, messages "called g. ">)
= feed(f, feed(g, <x, messages>))

That is the same as feeding the pair into g and feeding the resulting pair into f.

You have most of a monad. Now you just need to know about the data types in your program.

What type of value is <x, "called f. ">? Well, that depends on what type of value x is. If x is of type t, then your pair is a value of type "pair of t and string". Call that type M t.

M is a type constructor: M alone does not refer to a type, but M _ refers to a type once you fill in the blank with a type. An M int is a pair of an int and a string. An M string is a pair of a string and a string. etc.

Congratulations, you have created a monad!

Formally, your monad is the tuple <M, feed, wrap>.

A monad is a tuple <M, feed, wrap> where:

  • M is a type constructor.
  • feed takes a (function that takes a u and returns an M u) and an M t and returns an M u.
  • wrap takes a v and returns an M v.

t, u, and v are any three types that may or may not be the same. A monad satisfies the three properties you proved for your specific monad:

  • Feeding a wrapped t into a function is the same as passing the unwrapped t into the function.

    Formally: feed(f, wrap(x)) = f(x)

  • Feeding an M t into wrap does nothing to the M t.

    Formally: feed(wrap, m) = m

  • Feeding an M t (call it m) into a function that

    • passes the t into g
    • gets an M u (call it n) from g
    • feeds n into f

    is the same as

    • feeding m into g
    • getting n from g
    • feeding n into f

    Formally: feed(h, m) = feed(f, feed(g, m)) where h(x) := feed(f, g(x))

Typically, feed is called bind (a.k.a. >>= in Haskell) and wrap is called return.

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This is the video you are looking for.

Demonstrating in C# what the problem is with composition and aligning the types, and then implementing them properly in C#. Towards the end he displays how the same C# code looks in F# and finally in Haskell.

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mathematial thinking

for short: An Algebraic Structure for Combining Computations.

return data : create a computation who just simply generate a data in monad world.

(return data) >>= (return func) : The second parameter accept first parameter as a data generator and create a new computations which concatenate them.

you can think that (>>=) and return won't do any computation itself, they just simply combine and create computations.

Any monad computation will be compute if and only if main trig it.

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